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US6290690B1 - Simultaneous injection and aspiration of viscous fluids in a surgical system - Google Patents

️Tue Sep 18 2001

US6290690B1 - Simultaneous injection and aspiration of viscous fluids in a surgical system - Google Patents

Simultaneous injection and aspiration of viscous fluids in a surgical system Download PDF

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Publication number

US6290690B1

US6290690B1 US09/336,922 US33692299A US6290690B1 US 6290690 B1 US6290690 B1 US 6290690B1 US 33692299 A US33692299 A US 33692299A US 6290690 B1 US6290690 B1 US 6290690B1 Authority

United States

Prior art keywords

surgical system

pneumatic pressure

assembly

posterior segment

vacuum

Prior art date

1999-06-21

Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)

Expired - Lifetime

Application number

US09/336,922

Inventor

John C. Huculak

II Richard L. Zaleski

Russell L. Finlay

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

Alcon Inc

Original Assignee

Alcon Manufacturing Ltd

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1999-06-21

Filing date

1999-06-21

Publication date

2001-09-18

1999-06-21 Application filed by Alcon Manufacturing Ltd filed Critical Alcon Manufacturing Ltd

1999-06-21 Priority to US09/336,922 priority Critical patent/US6290690B1/en

1999-07-26 Assigned to ALCON LABORATORIES, INC. reassignment ALCON LABORATORIES, INC. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: ZALESKI, II, RICHARD L., FINLAY, RUSSELL L., HUCULAK, JOHN C.

2000-06-08 Priority to EP03001000A priority patent/EP1302185B8/en

2000-06-08 Priority to EP00942710A priority patent/EP1180993B1/en

2000-06-08 Priority to ES00942710T priority patent/ES2203491T3/en

2000-06-08 Priority to JP2001504326A priority patent/JP3845013B2/en

2000-06-08 Priority to DK00942710T priority patent/DK1180993T3/en

2000-06-08 Priority to AU57295/00A priority patent/AU758704B2/en

2000-06-08 Priority to CA002371877A priority patent/CA2371877C/en

2000-06-08 Priority to CA002547297A priority patent/CA2547297C/en

2000-06-08 Priority to PT00942710T priority patent/PT1180993E/en

2000-06-08 Priority to DE60004818T priority patent/DE60004818T2/en

2000-06-08 Priority to AT00942710T priority patent/ATE247939T1/en

2000-06-08 Priority to PCT/US2000/015803 priority patent/WO2000078257A1/en

2001-03-26 Assigned to ALCON MANUFACTURING, LTD. reassignment ALCON MANUFACTURING, LTD. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: ALCON LABORATORIES, INC.

2001-09-18 Publication of US6290690B1 publication Critical patent/US6290690B1/en

2001-09-18 Application granted granted Critical

2006-05-25 Priority to JP2006145723A priority patent/JP4602935B2/en

2008-07-21 Assigned to ALCON RESEARCH, LTD. reassignment ALCON RESEARCH, LTD. MERGER (SEE DOCUMENT FOR DETAILS). Assignors: ALCON MANUFACTURING, LTD.

2019-06-21 Anticipated expiration legal-status Critical

2019-12-10 Assigned to ALCON INC. reassignment ALCON INC. CONFIRMATORY DEED OF ASSIGNMENT EFFECTIVE APRIL 8, 2019 Assignors: NOVARTIS AG

2020-07-21 Assigned to ALCON RESEARCH, LLC reassignment ALCON RESEARCH, LLC MERGER (SEE DOCUMENT FOR DETAILS). Assignors: ALCON RESEARCH, LTD.

2020-07-23 Assigned to ALCON INC. reassignment ALCON INC. CONFIRMATORY DEED OF ASSIGNMENT EFFECTIVE APRIL 8, 2019 Assignors: ALCON RESEARCH, LLC

Status Expired - Lifetime legal-status Critical Current

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Classifications

- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61M—DEVICES FOR INTRODUCING MEDIA INTO, OR ONTO, THE BODY; DEVICES FOR TRANSDUCING BODY MEDIA OR FOR TAKING MEDIA FROM THE BODY; DEVICES FOR PRODUCING OR ENDING SLEEP OR STUPOR
- A61M1/00—Suction or pumping devices for medical purposes; Devices for carrying-off, for treatment of, or for carrying-over, body-liquids; Drainage systems
- A61M1/71—Suction drainage systems
- A61M1/77—Suction-irrigation systems
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B17/00—Surgical instruments, devices or methods
- A61B2017/00973—Surgical instruments, devices or methods pedal-operated
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B17/00—Surgical instruments, devices or methods
- A61B2017/00973—Surgical instruments, devices or methods pedal-operated
- A61B2017/00977—Surgical instruments, devices or methods pedal-operated the depression depth determining the power rate
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F9/00—Methods or devices for treatment of the eyes; Devices for putting in contact-lenses; Devices to correct squinting; Apparatus to guide the blind; Protective devices for the eyes, carried on the body or in the hand
- A61F9/007—Methods or devices for eye surgery
- A61F9/00727—Apparatus for retinal reattachment
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61F—FILTERS IMPLANTABLE INTO BLOOD VESSELS; PROSTHESES; DEVICES PROVIDING PATENCY TO, OR PREVENTING COLLAPSING OF, TUBULAR STRUCTURES OF THE BODY, e.g. STENTS; ORTHOPAEDIC, NURSING OR CONTRACEPTIVE DEVICES; FOMENTATION; TREATMENT OR PROTECTION OF EYES OR EARS; BANDAGES, DRESSINGS OR ABSORBENT PADS; FIRST-AID KITS
- A61F9/00—Methods or devices for treatment of the eyes; Devices for putting in contact-lenses; Devices to correct squinting; Apparatus to guide the blind; Protective devices for the eyes, carried on the body or in the hand
- A61F9/007—Methods or devices for eye surgery
- A61F9/00736—Instruments for removal of intra-ocular material or intra-ocular injection, e.g. cataract instruments

Definitions

the present invention generally pertains to apparatus and methods for providing simultaneous viscous fluid injection and aspiration in a surgical system. More particularly, but not by way of limitation, the present invention pertains to apparatus and methods for injecting a long-term viscous fluid tamponade into the posterior segment of the eye while simultaneously aspirating a short-term viscous fluid tamponade out of the eye during vitreoretinal surgery.
the retina In a healthy human eye, the retina is physically attached to the choroid in a generally circumferential manner behind the pars plana.
the vitreous humor a transparent jelly-like material that fills the posterior segment of the eye, helps to cause the remainder of the retina to lie against, but not physically attach, to the choroid.
a helpful analogy is to imagine the choroid as the walls of a swimming pool.
the retina is like a wallpaper that is pressed against the walls of the swimming pool by the water in the pool, but is only physically attached to the walls at the top of the pool.
a portion of the retina becomes detached from the choroid. Other times a portion of the retina may tear, allowing aqueous humor, and sometimes vitreous, to flow between the retina and the choroid. Both of these conditions result in a loss of vision.
a surgeon typically inserts a vitrectomy probe into the posterior segment of the eye via an incision through the sclera in the pars plana. Such an incision is called a scleratomy.
the surgeon typically also inserts a fiber optic light source and an infusion cannula into the eye via similar incisions, and may sometimes substitute an aspiration probe for the vitrectomy probe.
the surgeon While viewing the posterior segment under a microscope and with the aid of the fiber optic light source, the surgeon cuts and aspirates away vitreous using the vitrectomy probe to gain access to the retinal detachment or tear.
the surgeon may also use the vitrectomy probe, scissors, a pick, and/or forceps to remove any membrane that has contributed to the retinal detachment or tear.
a saline solution is typically infused into the eye via the infusion cannula to maintain the appropriate intraocular pressure.
perfluorocarbon liquids are toxic when left in the eye for a period of weeks. Since a retinal tear or detachment takes a period of weeks to re-attach after the above-described surgical procedure, the short-term perfluorocarbon liquid tamponade must be removed from the eye at the latter portion of the surgical procedure and replaced with a long-term tamponade.
This long-term tamponade can be an air/gas mixture or a viscous fluid, such as silicone oil. If silicone oil is used, it too must be extracted from the eye after the retina re-attaches because it is toxic when left in the eye for a period of months.
surgeons employ several techniques to perform this replacement of perfluorocarbon liquid with silicone oil, which is sometimes called a “fluid/fluid exchange”.
a conventional vitreoretinal surgical system to inject silicone oil via a system generated injection pressure and an infusion cannula.
An exemplary system is the Accurus® surgical system sold by Alcon Laboratories, Inc. of Fort Worth, Tex.
As the silicone oil is injected pressure increases in the eye.
the increased pressure in the eye causes the perfluorocarbon liquid to passively flow into an extrusion cannula connected to the aspiration probe.
the aspiration probe removes the perfluorocarbon liquid from the eye.
this technique requires the use of larger diameter (e.g.
a surgeon may use such a conventional vitreoretinal surgical system to inject silicone oil via a system generated infusion pressure and an infusion cannula.
the surgeon switches the mode of operation of the surgical system so that it provides vacuum for the aspiration probe instead of injection pressure for the infusion cannula.
the surgeon then utilizes the aspiration probe with extrusion cannula to aspirate perfluorocarbon liquid from the eye to counteract the above-described rise in intraocular pressure.
the surgeon reconfigures the surgical system for injection pressure and injects more silicone oil into the posterior segment of the eye. This cycling between injecting silicone oil and aspirating perfluorocarbon liquid is continued until all the perfluorocarbon liquid is replaced with silicone oil.
the surgeon visually monitors the eye in an attempt to prevent the intraocular pressure from rising to a dangerously high level (a “hard eye” condition) or a dangerously low level (a “soft eye” condition).
a dangerously high level a “hard eye” condition
a dangerously low level a “soft eye” condition
this cycling is required because conventional vitreoretinal surgical systems are not capable of supplying simultaneous injection and aspiration of viscous fluids.
the intraocular pressure can vary above and below a desired intraocular pressure. This variance of the intraocular pressure may cause difficulty for the surgeon during the procedure, can be detrimental to the patient, and is especially prevalent with the preferred use of tapered and soft tip extrusion cannulas.
the surgeon may employ the technique of using a conventional vitreoretinal surgical system and an aspiration probe to aspirate perfluorocarbon liquid, and a second, separate system to inject silicone oil.
the use of two systems allows the simultaneous injection and aspiration of viscous fluids into the eye.
the use of two systems requires the surgeon to operate and control both systems simultaneously, which can be difficult.
the surgeon may be forced to utilize additional staff to help with the operation of at least one of the systems.
the surgeon may utilize an air/gas mixture as a long-term tamponade.
the surgeon infuses air while all of the saline, resulting from the vitrectomy process, is aspirated.
the air acts to re-position the retina against the choroid.
a mixture of air and gas typically a perfluorocarbon gas
the air/gas mixture is of a specific proportion resulting in an expanding air/gas bubble having an expansion rate that closely matches the rate at which air leaks from the eye.
the air/gas bubble helps prevent regenerated aqueous humor from wetting the retina before it has had sufficient time to re-attach.
the bubble typically lasts several days.
the use of an air/gas mixture as a long-term tamponade requires a very compliant patient. For example, patients must hold their head in certain positions for several hours a day to insure that the air/gas bubble prevents aqueous humor from wetting the retina. This type of long-term tamponade is therefore not suitable for elderly, young, and mentally disabled patients, or patients requiring air travel.
such “fluid/air” and “air/gas” exchanges can result in slippage of the retina, procedural complications, and more surgeon time.
One aspect of the present invention comprises a method of injecting a first viscous fluid into a posterior segment of an eye simultaneous with aspirating a second viscous fluid from the posterior segment.
a surgical system is provided that is capable of supplying pneumatic pressure and vacuum.
a first viscous fluid is injected into the posterior segment using pneumatic pressure from the system.
a mode of operation of the system is changed to provide vacuum and pneumatic pressure.
the second viscous fluid is aspirated from the posterior segment using vacuum from the system, and the pneumatic pressure exhibits a decrease of about twelve percent or less during the aspirating stcp.
the present invention comprises a surgical system for injecting a first viscous fluid into a target tissue simultaneous with aspirating a second viscous fluid from the target tissue.
the surgical system includes an assembly capable of supplying pneumatic pressure and vacuum to at least one microsurgical instrument, and a foot pedal operatively coupled to the assembly.
the foot pedal includes a first range of motion in a generally vertical plane in which the assembly supplies proportional pneumatic pressure, and a second range of motion in a generally vertical plane in which the assembly supplies a substantially constant pneumatic pressure and proportional vacuum.
the present invention comprises a surgical system for injecting a first retinal tamponading fluid into a posterior segment of an eye simultaneous with aspirating a second retinal tamponading fluid from the posterior segment.
the system includes a single pneumatic assembly capable of supplying pneumatic pressure and vacuum.
the system also includes a syringe having a hollow bore with a first end and a second end, and a plunger movably disposed in the hollow bore between the first and second ends.
the system further includes tubing fluidly coupling the first end of the hollow bore to the assembly. A volume of the tubing and the hollow bore on a side of the plunger nearest to the first end is greater than the volume of the posterior segment. This volume of the tubing and the hollow bore allows the assembly to supply a substantially constant pneumatic pressure to the side of the plunger nearest to the first end of the hollow bore simultaneous with supplying vacuum to aspirate the second retinal tamponading fluid.
FIG. 1 is a schematic, fragmentary, partially sectional illustration of a surgical system for injecting a viscous fluid into a human eye while simultaneously aspirating a second viscous fluid from the eye according to a preferred embodiment of the present invention
FIG. 2 is a block diagram of certain portions of the electronic and pneumatic subassemblies of the surgical system of FIG. 1;
FIG. 3 shows a preferred embodiment of a pneumatic reservoir of the surgical system of FIG. 1;
FIG. 4 is a schematic illustration of a preferred embodiment of a foot pedal of the surgical system of FIG. 1;
FIG. 5 is a graphic illustration of the change in injection pressure in the surgical system of FIG. 1 .
FIGS. 1 through 5 of the drawings like numerals being used for like and corresponding parts of the various drawings.
FIG. 1 shows a schematic illustration of a surgical system 10 injecting a viscous fluid 12 into a posterior segment 13 of a human eye 14 while simultaneously aspirating a second viscous fluid 16 out of eye 14 according to a preferred method of the present invention.
Surgical system 10 is preferably a conventional surgical system capable of performing vitreoretinal surgery that has been modified according to the present invention.
An exemplary surgical system 10 suitable for such modification is the Accurus® surgical system sold by Alcon Laboratories, Inc.
viscous fluid 12 is preferably silicone oil
viscous fluid 16 is preferably perfluorocarbon liquid.
a saline solution 18 is typically present within posterior segment 13 .
Silicone oil 12 preferably has a viscosity of about 1000 to about 5000 centistokes.
Perfluorocarbon liquid 16 preferably has a viscosity of about 6 to about 7 centistokes.
Saline solution 18 preferably has a viscosity of about 1 centistoke.
An exemplary silicone oil suitable for use as silicone oil 12 is the SilikonTM silicone oil available from Alcon Laboratories, Inc.
An exemplary perfluorocarbon liquid suitable for perfluorocarbon liquid 16 is Perfluoron® perfluorocarbon liquid sold by Alcon Laboratories, Inc.
An exemplary saline solution suitable for saline solution 18 is BSS PLUS® intraocular irrigating solution sold by Alcon Laboratories, Inc.
Eye 14 has a cornea 20 , a lens 22 , a sclera 24 , a choroid 26 , a retina 28 , and an optic nerve 30 .
Cornea 20 and lens 22 generally define an anterior segment 32 of eye 14 .
Lens 22 , choroid 26 , and retina 28 generally define posterior segment 13 of eye 14 .
Retina 28 is physically attached to choroid 26 in a circumferential manner proximate pars plana 34 .
eye 14 has undergone a vitrectomy process in which the vitreous humor has been cut and aspirated out of posterior segment 13 , as described hereinabove.
saline solution 18 was infused into eye 14 via an infusion cannula 62 to maintain the appropriate intraocular pressure.
a detached portion or tear 36 of retina 28 was repositioned by injecting perfluorocarbon liquid 16 into posterior segment 13 via an injection cannula and syringe (not shown) to cause detached portion or tear 36 to flatten against choroid 26 in the proper location.
a diathermy probe or a laser was used to fuse portion or tear 36 in place.
a conventional fiber optic light source 38 provided light for the surgeon, who viewed posterior segment 13 via a microscope.
Light source 38 is inserted into posterior segment 13 via a scleratomy 39 .
Light source 38 is preferably operatively coupled to a port 40 of surgical system 10 via light fiber cabling 42 .
perfluorocarbon liquid 16 is toxic when left in eye 14 for a period of weeks. Since detached portion or tear 36 of retina 28 requires a period of weeks to re-attach after the above-described surgical procedure, perfluorocarbon liquid 16 is only acceptable as a short-term tamponade to hold portion or tear 36 of retina 28 in the proper location against choroid 26 . Therefore, perfluorocarbon liquid 16 is removed from eye 14 and replaced with silicone oil 12 , a long-term tamponade.
Surgical system 10 includes a port 50 capable of providing proportional pressure to a microsurgical instrument connected thereto.
port 50 is fluidly coupled to an end 54 of a conventional syringe 56 via tubing 58 .
a second end 60 of syringe 56 is fluidly coupled to infusion cannula 62 via tubing 64 .
Tubing 58 and 64 are preferably conventional PVC tubing.
Infusion cannula 62 is inserted into posterior segment 13 via a scleratomy 66 .
Syringe 56 has a plunger 68 movably disposed within its hollow body 70 .
Surgical system 10 also includes a port 52 capable of providing proportional vacuum to a microsurgical instrument attached thereto.
Port 52 is preferably a part of conventional surgical cassette 72 that helps manage the aspiration flows of surgical system 10 .
U.S. Pat. Nos. 4,493,695; 4,627,833 (Cook); 4,395,258 (Wang et al.); 4,713,051 (Steppe et al.); 4,798,850 (DeMeo et al.); 4,758,238; 4,790,816 (Sundblom et al.); 5,267,956; and 5,364,342 (Beuchat) all disclose tubeless or tube-type surgical cassettes and arc incorporated herein in their entirety by reference.
a collection bag 74 is fluidly coupled to surgical cassette 72 .
port 52 is fluidly coupled to an aspiration probe 76 having an extrusion cannula 77 via tubing 78 .
Tubing 78 is preferably conventional PVC tubing.
Aspiration probe 76 and extrusion cannula 77 are inserted into posterior segment 13 via a scleratomy 80 .
FIG. 2 shows a block diagram of certain portions of the electronic and pneumatic sub-assemblies of surgical system 10 .
Surgical system 10 includes a regulated pneumatic pressure source 100 that is fluidly coupled to a proportional valve 102 via an input manifold 104 .
Pressure source 100 preferably supplies a constant source of pneumatic pressure on the order of about 85 psi.
a suitable proportional valve for valve 102 is Model No. 002 -AXXAVCAA sold by Porter Instrument Company, Inc. of Hatfield, Pa. Of course, other proportional valves may be used for valve 102 .
Proportional valve 102 is fluidly coupled to a solenoid valve 103 via a first valve output manifold 105 .
a vacuum pump or venturi 106 is fluidly coupled to solenoid valve 103 via a manifold 108 .
a suitable vacuum pump (venturi) for pump 106 is Model No. LX10 sold by PIAB of Hingham, Mass. Of course, other pumps or venturis may be used for pump 106 .
Pump 106 has a vacuum manifold 110 that is fluidly coupled to a volume 72 a of surgical cassette 72 and to port 52 . Pump 106 also has an exhaust manifold 112 .
proportional valve 102 is fluidly coupled to a solenoid valve 150 via a second valve output manifold 114 .
a reservoir 151 is fluidly coupled to solenoid valve 150 via a manifold 115 .
a manifold 116 fluidly couples reservoir 151 to port 50 .
a surgeon can switch the output of proportional valve 102 by opening and closing solenoid valves 103 and 150 .
solenoid valve 103 When solenoid valve 103 is open and solenoid valve 150 is closed, proportional valve 102 supplies vacuum to port 52 .
solenoid valve 150 When solenoid valve 150 is open and solenoid valve 103 is closed, proportional valve 102 supplies pneumatic pressure to port 50 .
variable input device 120 is preferably a foot switch or foot pedal. Foot pedal 120 is operatively coupled to proportional valve 102 via conventional electronic cabling 122 .
a surgeon chooses the desired level of vacuum for port 52 or pressure for port 50 by manipulating foot pedal 120 to generate an input signal 124 for proportional valve 102 . More specifically, the surgeon can gradually open proportional valve 102 by depressing foot pedal 120 and can gradually close proportional valve 102 by “letting up” on foot pedal 120 .
the degree to which proportional valve 102 is open determines the pressure and air flow rate delivered to manifold 105 or manifold 114 .
a process control system is preferably operatively coupled to proportional valve 102 , vacuum pump 106 , vacuum manifold 110 , second valve output manifold 114 , and foot pedal 102 so as to give the surgeon precise control of the microsurgical instruments coupled to ports 50 or 52 of surgical system 10 .
the preferred process control system is described in detail in U.S. Pat. No. 5,674,194, which is commonly owned with the present invention and is incorporated herein in its entirety by reference.
FIG. 3 illustrates preferred embodiments of solenoid valve 150 and reservoir 151 .
Tubing 152 supplies pneumatic pressure from second valve output manifold 114 to solenoid valve 150 , manifold 115 , reservoir 151 , manifold 116 , and port or pneumatic connector 50 .
Tubing 152 is preferably conventional PVC tubing.
Tubing 152 , solenoid valve 150 , manifold 115 , reservoir 151 , and manifold 116 are preferably located within housing 11 of surgical system 10 generally behind port 50 .
reservoir 151 may also be located external to housing 11 of surgical system 10 .
reservoir 151 may be fluidly coupled to tubing 58 , as shown schematically in FIG. 1 .
syringe 56 may be modified from its conventional form to include reservoir 151 proximate its end 54 .
the length and/or inner diameter of tubing 58 may be modified from its conventional form so as to incorporate the volume of reservoir 151 .
FIG. 4 schematically illustrates a preferred embodiment of foot pedal 120 according to the present invention.
Foot pedal 120 has a first position 200 corresponding to a fully undepressed position, a second position 202 corresponding to a fully depressed position, and a third position 204 corresponding to an about one-third depressed position.
Position 204 is preferably indicated by a mechanical detent of foot pedal 120 .
Foot pedal 120 may be made by modifying the conventional foot pedal sold as part of the Accurus® surgical system mentioned hereinabove.
a conventional surgical system 10 is limited by the fact that it cannot supply pneumatic pressure to port 50 for the injection of viscous fluid 12 into eye 14 simultaneously with supplying vacuum to port 52 for the aspiration of viscous fluid 16 from eye 14 .
solenoid valve 150 the addition of solenoid valve 150 , reservoir 151 , and manifolds 115 and 116 enable the delivery of a substantially constant pneumatic pressure to port 50 while proportional vacuum is also provided to port 52 .
this ability allows the surgeon to minimize the potential of slippage of retina 28 and to maintain the intraocular pressure of eye 14 at a level very close to the desired intraocular pressure during the fluid/fluid exchange.
a first volume V 1 may be defined by the volume of air within manifold 115 , reservoir 151 , manifold 116 , tubing 58 , and syringe 56 on the side of plunger 68 proximate tubing 58 .
a second volume V 2 may be defined by the volume of posterior segment 13 of eye 14 to be filled with silicone oil 12 .
silicone oil 12 is injected into eye 14
syringe plunger 68 moves toward end 60 of syringe 56 , increasing the volume of V 1 by the amount of oil injected.
volume V 1 will have increased by an amount V 2 .
FIG. 5 further illustrates how reservoir 151 functions to keep silicone oil injection pressure P 1 substantially constant during the injection of silicone oil 12 .
tubing 58 and syringe 56 on the side of plunger 68 proximate tubing 58 have a volume V 0 of about twenty two (22) cubic centimeters, and reservoir 151 has a volume of about 12.5 cubic centimeters.
the volume V 2 of posterior segment 13 to be filled with silicone oil 12 is about 5 cubic centimeters.
V 0 was increased by V 2 , as would occur during the injection of 5 cubic centimeters of silicone oil, an injection pressure P 0 of about 40 psi decreased about 7 psig (about 17.5 percent).
an injection pressure P 1 of about 40 psi decreased only about 4.8 psig (about 12 percent) when V 1 was increased by V 2 .
an injection pressure P 0 of about 80 psi decreased about 14 psig (about 17.5 percent) when V 0 was increased by V 2 .
an injection pressure P 1 of about 80 psi decreased only about 9.8 psig (about 12 percent) when V 1 was increased by V 2 .
Similar variances of P 1 were observed for injection pressures of 50 psi, 60 psi, and 70 psi, as shown in FIG. 5 .
Boyle's Law shows that the variance of P 1 may be reduced below 12 percent by increasing the volume of reservoir 151 , if desired, for specific surgical systems 10 . For example, this variance of P 1 may be reduced to 10 percent, 8 percent, 6 percent, 4 percent, 2 percent, or below.
FIGS. 1 through 5 the preferred method of operating foot pedal 120 according to the present invention so as to perform a fluid/fluid exchange of perfluorocarbon liquid 16 and siliconc oil 12 is described in greater detail.
proportional valve 102 does not supply pneumatic pressure or vacuum to ports 50 or 52 , respectively.
Solenoid valve 103 is in the closed position, and solenoid valve 150 is in the open position. Silicone oil 12 is not being injected into posterior segment 13 via infusion cannula 62 , and perfluorocarbon liquid 16 is not being aspirated via aspiration probe 76 .
pneumatic pressure is supplied to manifold 115 , reservoir 151 , manifold 116 , port 50 , tubing 58 , and syringe 56 in gradually increasing amounts. This is accomplished via a change in electrical signal 124 from foot pedal 120 to proportional valve 102 communicated via electrical cabling 122 .
the minimum pneumatic pressure is preferably 0 psi (position 200 ), and the maximum pneumatic pressure is preferably about 80 psi (position 204 ).
Such proportional pneumatic pressure causes silicone oil 12 from syringe 56 and tubing 64 to be injected into posterior segment 13 via infusion cannula 62 .
a clamping mechanism (not shown) within surgical cassette 72 is preferably in the closed position to prevent passive flow of perfluorocarbon liquid 16 into surgical cassette 72 . Therefore, the intraocular pressure of eye 14 gradually begins to rise.
solenoid valve 150 closes solenoid valve 150 and open solenoid valve 103 , fluidly coupling vacuum pump 106 to first valve output manifold 105 .
Closure of solenoid valve 150 causes the injection pressure P 1 in manifold 115 , reservoir 151 , manifold 116 , port 50 , tubing 58 , and syringe 56 to be maintained, resulting in the continued flow of silicone oil into eye 14 via tubing 64 .
the printed circuit board electronics of surgical system 10 actuate the clamping mechanism within surgical cassette 72 to an open position allowing flow of perfluorocarbon liquid 16 from tubing 78 into cassette 72 .
the surgeon lets up on foot pedal 120 , controlling the flow of aspirated perfluorocarbon liquid 16 to more closely match the injection flow rate of silicone oil 12 . In this manner, the surgeon quickly brings the intraocular pressure to its desired level.
the present invention provides improved apparatus and methods for tamponading a retinal tear or detachment.
the present invention minimizes retinal slippage and variations in intraocular pressure during a fluid/fluid exchange.
the present invention also provides the surgeon with an easier method of controlling a fluid/fluid exchange.
the present invention is illustrated herein by example, and various modifications may be made by a person of ordinary skill in the art.
the preferred apparatus and methods are described hereinabove in connection with a fluid/fluid exchange of perfluorocarbon liquid and silicone oil in vitreoretinal surgery, the present invention is applicable to the simultaneous injection and aspiration of other viscous fluids.
the present invention is also applicable to other types of surgeries other than vitreoretinal surgery.

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Abstract

A method of injecting a first viscous fluid into a target tissue simultaneous with aspirating a second viscous fluid from the target tissue is disclosed. A surgical system is provided that is capable of supplying pneumatic pressure and vacuum. A first viscous fluid is injected into the target tissue using pneumatic pressure from the system. A mode of operation of the system is changed to provide vacuum and pneumatic pressure. The second viscous fluid is aspirated from the target tissue using vacuum from the system, and the pneumatic pressure remains substantially constant during aspiration. An improved foot pedal for controlling the simultaneous injection and aspiration of viscous fluids is also disclosed.

Description

FIELD OF THE INVENTION

The present invention generally pertains to apparatus and methods for providing simultaneous viscous fluid injection and aspiration in a surgical system. More particularly, but not by way of limitation, the present invention pertains to apparatus and methods for injecting a long-term viscous fluid tamponade into the posterior segment of the eye while simultaneously aspirating a short-term viscous fluid tamponade out of the eye during vitreoretinal surgery.

DESCRIPTION OF THE RELATED ART

In a healthy human eye, the retina is physically attached to the choroid in a generally circumferential manner behind the pars plana. The vitreous humor, a transparent jelly-like material that fills the posterior segment of the eye, helps to cause the remainder of the retina to lie against, but not physically attach, to the choroid. A helpful analogy is to imagine the choroid as the walls of a swimming pool. The retina is like a wallpaper that is pressed against the walls of the swimming pool by the water in the pool, but is only physically attached to the walls at the top of the pool.

Sometimes a portion of the retina becomes detached from the choroid. Other times a portion of the retina may tear, allowing aqueous humor, and sometimes vitreous, to flow between the retina and the choroid. Both of these conditions result in a loss of vision.

To surgically repair these conditions, a surgeon typically inserts a vitrectomy probe into the posterior segment of the eye via an incision through the sclera in the pars plana. Such an incision is called a scleratomy. The surgeon typically also inserts a fiber optic light source and an infusion cannula into the eye via similar incisions, and may sometimes substitute an aspiration probe for the vitrectomy probe. While viewing the posterior segment under a microscope and with the aid of the fiber optic light source, the surgeon cuts and aspirates away vitreous using the vitrectomy probe to gain access to the retinal detachment or tear. The surgeon may also use the vitrectomy probe, scissors, a pick, and/or forceps to remove any membrane that has contributed to the retinal detachment or tear. During this portion of the surgery, a saline solution is typically infused into the eye via the infusion cannula to maintain the appropriate intraocular pressure.

Next, many surgeons inject a perfluorocarbon liquid into the posterior segment of the eye to cause the detached or torn portion of the retina to flatten against the choroid in the proper location. Once the detached or torn portion of the retina is properly located, the surgeon uses a diathermy probe or a laser to fuse portions of the detached retina in place.

Unfortunately, perfluorocarbon liquids are toxic when left in the eye for a period of weeks. Since a retinal tear or detachment takes a period of weeks to re-attach after the above-described surgical procedure, the short-term perfluorocarbon liquid tamponade must be removed from the eye at the latter portion of the surgical procedure and replaced with a long-term tamponade. This long-term tamponade can be an air/gas mixture or a viscous fluid, such as silicone oil. If silicone oil is used, it too must be extracted from the eye after the retina re-attaches because it is toxic when left in the eye for a period of months.

Conventionally, surgeons employ several techniques to perform this replacement of perfluorocarbon liquid with silicone oil, which is sometimes called a “fluid/fluid exchange”. First, the surgeon may use a conventional vitreoretinal surgical system to inject silicone oil via a system generated injection pressure and an infusion cannula. An exemplary system is the Accurus® surgical system sold by Alcon Laboratories, Inc. of Fort Worth, Tex. As the silicone oil is injected, pressure increases in the eye. The increased pressure in the eye causes the perfluorocarbon liquid to passively flow into an extrusion cannula connected to the aspiration probe. The aspiration probe removes the perfluorocarbon liquid from the eye. Unfortunately, this technique requires the use of larger diameter (e.g. straight 20 gage) extrusion cannulas to allow sufficient passive flow without excessively elevated intraocular pressure. In contrast, surgeons prefer to use tapered and/or soft tip extrusion cannulas due to the additional level of safety provided should they accidentally come in contact with the retina.

Second, a surgeon may use such a conventional vitreoretinal surgical system to inject silicone oil via a system generated infusion pressure and an infusion cannula. As the intraocular pressure increases, the surgeon switches the mode of operation of the surgical system so that it provides vacuum for the aspiration probe instead of injection pressure for the infusion cannula. The surgeon then utilizes the aspiration probe with extrusion cannula to aspirate perfluorocarbon liquid from the eye to counteract the above-described rise in intraocular pressure. Next, the surgeon reconfigures the surgical system for injection pressure and injects more silicone oil into the posterior segment of the eye. This cycling between injecting silicone oil and aspirating perfluorocarbon liquid is continued until all the perfluorocarbon liquid is replaced with silicone oil. In this technique, the surgeon visually monitors the eye in an attempt to prevent the intraocular pressure from rising to a dangerously high level (a “hard eye” condition) or a dangerously low level (a “soft eye” condition). In addition, it is important to note that this cycling is required because conventional vitreoretinal surgical systems are not capable of supplying simultaneous injection and aspiration of viscous fluids. However, even when this technique is performed successfully, the intraocular pressure can vary above and below a desired intraocular pressure. This variance of the intraocular pressure may cause difficulty for the surgeon during the procedure, can be detrimental to the patient, and is especially prevalent with the preferred use of tapered and soft tip extrusion cannulas.

Third, the surgeon may employ the technique of using a conventional vitreoretinal surgical system and an aspiration probe to aspirate perfluorocarbon liquid, and a second, separate system to inject silicone oil. The use of two systems allows the simultaneous injection and aspiration of viscous fluids into the eye. However, the use of two systems requires the surgeon to operate and control both systems simultaneously, which can be difficult. The surgeon may be forced to utilize additional staff to help with the operation of at least one of the systems.

As mentioned hereinabove, different methods of tamponading the retina after vitreoretinal surgery exist that do not require the use of perfluorocarbon liquids. For example, the surgeon may utilize an air/gas mixture as a long-term tamponade. In this technique, the surgeon infuses air while all of the saline, resulting from the vitrectomy process, is aspirated. The air acts to re-position the retina against the choroid. A mixture of air and gas (typically a perfluorocarbon gas) is then injected into the air-filled eye replacing the infused air. The air/gas mixture is of a specific proportion resulting in an expanding air/gas bubble having an expansion rate that closely matches the rate at which air leaks from the eye. The air/gas bubble helps prevent regenerated aqueous humor from wetting the retina before it has had sufficient time to re-attach. The bubble typically lasts several days. Unfortunately, the use of an air/gas mixture as a long-term tamponade requires a very compliant patient. For example, patients must hold their head in certain positions for several hours a day to insure that the air/gas bubble prevents aqueous humor from wetting the retina. This type of long-term tamponade is therefore not suitable for elderly, young, and mentally disabled patients, or patients requiring air travel. In addition, during large retinal tear or detachment procedures, such “fluid/air” and “air/gas” exchanges can result in slippage of the retina, procedural complications, and more surgeon time.

Therefore, a need exists in vitreoretinal surgery for a surgical system and a method that provides long-term tamponading of the retina without the above-described limitations. The system and method should be easy for the surgeon to use, should maximize patient safety, and should be economically feasible.

SUMMARY OF THE INVENTION

One aspect of the present invention comprises a method of injecting a first viscous fluid into a posterior segment of an eye simultaneous with aspirating a second viscous fluid from the posterior segment. A surgical system is provided that is capable of supplying pneumatic pressure and vacuum. A first viscous fluid is injected into the posterior segment using pneumatic pressure from the system. A mode of operation of the system is changed to provide vacuum and pneumatic pressure. The second viscous fluid is aspirated from the posterior segment using vacuum from the system, and the pneumatic pressure exhibits a decrease of about twelve percent or less during the aspirating stcp.

In another aspect, the present invention comprises a surgical system for injecting a first viscous fluid into a target tissue simultaneous with aspirating a second viscous fluid from the target tissue. The surgical system includes an assembly capable of supplying pneumatic pressure and vacuum to at least one microsurgical instrument, and a foot pedal operatively coupled to the assembly. The foot pedal includes a first range of motion in a generally vertical plane in which the assembly supplies proportional pneumatic pressure, and a second range of motion in a generally vertical plane in which the assembly supplies a substantially constant pneumatic pressure and proportional vacuum.

In another aspect, the present invention comprises a surgical system for injecting a first retinal tamponading fluid into a posterior segment of an eye simultaneous with aspirating a second retinal tamponading fluid from the posterior segment. The system includes a single pneumatic assembly capable of supplying pneumatic pressure and vacuum. The system also includes a syringe having a hollow bore with a first end and a second end, and a plunger movably disposed in the hollow bore between the first and second ends. The system further includes tubing fluidly coupling the first end of the hollow bore to the assembly. A volume of the tubing and the hollow bore on a side of the plunger nearest to the first end is greater than the volume of the posterior segment. This volume of the tubing and the hollow bore allows the assembly to supply a substantially constant pneumatic pressure to the side of the plunger nearest to the first end of the hollow bore simultaneous with supplying vacuum to aspirate the second retinal tamponading fluid.

BRIEF DESCRIPTION OF THE DRAWINGS

For a more complete understanding of the present invention, and for further objects and advantages thereof, reference is made to the following description taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic, fragmentary, partially sectional illustration of a surgical system for injecting a viscous fluid into a human eye while simultaneously aspirating a second viscous fluid from the eye according to a preferred embodiment of the present invention;

FIG. 2 is a block diagram of certain portions of the electronic and pneumatic subassemblies of the surgical system of FIG. 1;

FIG. 3 shows a preferred embodiment of a pneumatic reservoir of the surgical system of FIG. 1;

FIG. 4 is a schematic illustration of a preferred embodiment of a foot pedal of the surgical system of FIG. 1; and

FIG. 5 is a graphic illustration of the change in injection pressure in the surgical system of FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The preferred embodiments of the present invention and their advantages are best understood by referring to FIGS. 1 through 5 of the drawings, like numerals being used for like and corresponding parts of the various drawings.

FIG. 1 shows a schematic illustration of a

surgical system

10 injecting a

viscous fluid

12 into a

posterior segment

13 of a

human eye

14 while simultaneously aspirating a second

viscous fluid

16 out of

eye

14 according to a preferred method of the present invention.

Surgical system

10 is preferably a conventional surgical system capable of performing vitreoretinal surgery that has been modified according to the present invention. An exemplary

surgical system

10 suitable for such modification is the Accurus® surgical system sold by Alcon Laboratories, Inc. When

surgical system

10 is used to perform a “fluid/fluid exchange” as a portion of a surgery to repair a detached or torn retina,

viscous fluid

12 is preferably silicone oil, and

viscous fluid

16 is preferably perfluorocarbon liquid. In addition, a

saline solution

18 is typically present within

posterior segment

13.

Silicone oil

12 preferably has a viscosity of about 1000 to about 5000 centistokes. Perfluorocarbon liquid 16 preferably has a viscosity of about 6 to about 7 centistokes.

Saline solution

18 preferably has a viscosity of about 1 centistoke. An exemplary silicone oil suitable for use as

silicone oil

12 is the Silikon™ silicone oil available from Alcon Laboratories, Inc. An exemplary perfluorocarbon liquid suitable for

perfluorocarbon liquid

16 is Perfluoron® perfluorocarbon liquid sold by Alcon Laboratories, Inc. An exemplary saline solution suitable for

saline solution

18 is BSS PLUS® intraocular irrigating solution sold by Alcon Laboratories, Inc.

Eye

14 has a

cornea

20, a

lens

22, a

sclera

24, a

choroid

26, a

retina

28, and an

optic nerve

30.

Cornea

20 and

lens

22 generally define an

anterior segment

32 of

eye

14.

Lens

22,

choroid

26, and

retina

28 generally define

posterior segment

13 of

eye

14.

Retina

28 is physically attached to

choroid

26 in a circumferential manner proximate pars plana 34.

As shown in FIG. 1,

eye

14 has undergone a vitrectomy process in which the vitreous humor has been cut and aspirated out of

posterior segment

13, as described hereinabove. During this process,

saline solution

18 was infused into

eye

14 via an

infusion cannula

62 to maintain the appropriate intraocular pressure. Also during this process, a detached portion or tear 36 of

retina

28 was repositioned by injecting

perfluorocarbon liquid

16 into

posterior segment

13 via an injection cannula and syringe (not shown) to cause detached portion or tear 36 to flatten against

choroid

26 in the proper location. Once portion or tear 36 was properly located, a diathermy probe or a laser (not shown) was used to fuse portion or tear 36 in place. During this process, a conventional fiber optic

light source

38 provided light for the surgeon, who viewed

posterior segment

13 via a microscope.

Light source

38 is inserted into

posterior segment

13 via a

scleratomy

39.

Light source

38 is preferably operatively coupled to a

port

40 of

surgical system

10 via

light fiber cabling

42.

As described hereinabove,

perfluorocarbon liquid

16 is toxic when left in

eye

14 for a period of weeks. Since detached portion or tear 36 of

retina

28 requires a period of weeks to re-attach after the above-described surgical procedure,

perfluorocarbon liquid

16 is only acceptable as a short-term tamponade to hold portion or tear 36 of

retina

28 in the proper location against

choroid

26. Therefore,

perfluorocarbon liquid

16 is removed from

eye

14 and replaced with

silicone oil

12, a long-term tamponade.

Surgical system

10 includes a

port

50 capable of providing proportional pressure to a microsurgical instrument connected thereto. For the preferred fluid/fluid exchange of the present invention,

port

50 is fluidly coupled to an

end

54 of a

conventional syringe

56 via

tubing

58. A

second end

60 of

syringe

56 is fluidly coupled to

infusion cannula

62 via

tubing

64.

Tubing

58 and 64 are preferably conventional PVC tubing.

Infusion cannula

62 is inserted into

posterior segment

13 via a scleratomy 66.

Syringe

56 has a

plunger

68 movably disposed within its

hollow body

70.

Surgical system

10 also includes a

port

52 capable of providing proportional vacuum to a microsurgical instrument attached thereto.

Port

52 is preferably a part of conventional

surgical cassette

72 that helps manage the aspiration flows of

surgical system

10. U.S. Pat. Nos. 4,493,695; 4,627,833 (Cook); 4,395,258 (Wang et al.); 4,713,051 (Steppe et al.); 4,798,850 (DeMeo et al.); 4,758,238; 4,790,816 (Sundblom et al.); 5,267,956; and 5,364,342 (Beuchat) all disclose tubeless or tube-type surgical cassettes and arc incorporated herein in their entirety by reference. A

collection bag

74 is fluidly coupled to

surgical cassette

72.

For the preferred fluid/fluid exchange of the present invention,

port

52 is fluidly coupled to an aspiration probe 76 having an

extrusion cannula

77 via

tubing

78.

Tubing

78 is preferably conventional PVC tubing. Aspiration probe 76 and

extrusion cannula

77 are inserted into

posterior segment

13 via a

scleratomy

80.

FIG. 2 shows a block diagram of certain portions of the electronic and pneumatic sub-assemblies of

surgical system

10.

Surgical system

10 includes a regulated pneumatic pressure source 100 that is fluidly coupled to a

proportional valve

102 via an

input manifold

104. Pressure source 100 preferably supplies a constant source of pneumatic pressure on the order of about 85 psi. A suitable proportional valve for

valve

102 is Model No. 002-AXXAVCAA sold by Porter Instrument Company, Inc. of Hatfield, Pa. Of course, other proportional valves may be used for

valve

102.

Proportional valve

102 is fluidly coupled to a

solenoid valve

103 via a first

valve output manifold

105. A vacuum pump or

venturi

106 is fluidly coupled to

solenoid valve

103 via a

manifold

108. A suitable vacuum pump (venturi) for

pump

106 is Model No. LX10 sold by PIAB of Hingham, Mass. Of course, other pumps or venturis may be used for

pump

106.

Pump

106 has a

vacuum manifold

110 that is fluidly coupled to a

volume

72 a of

surgical cassette

72 and to

port

52. Pump 106 also has an

exhaust manifold

112. In addition,

proportional valve

102 is fluidly coupled to a

solenoid valve

150 via a second

valve output manifold

114. A

reservoir

151 is fluidly coupled to

solenoid valve

150 via a

manifold

115. A manifold 116

fluidly couples reservoir

151 to

port

50. The above-described portions of

surgical system

10 in FIG. 2, with the exception of

solenoid valves

103 and 150,

reservoir

151, and

manifolds

115 and 116, are conventional.

As is explained in more detail hereinbelow, a surgeon can switch the output of

proportional valve

102 by opening and closing

solenoid valves

103 and 150. When

solenoid valve

103 is open and

solenoid valve

150 is closed,

proportional valve

102 supplies vacuum to

port

52. When

solenoid valve

150 is open and

solenoid valve

103 is closed,

proportional valve

102 supplies pneumatic pressure to

port

50.

surgical system

10, the surgeon chooses the desired vacuum or pressure level by manipulating a

variable input device

120.

Variable input device

120 is preferably a foot switch or foot pedal.

Foot pedal

120 is operatively coupled to

proportional valve

102 via conventional electronic cabling 122. A surgeon chooses the desired level of vacuum for

port

52 or pressure for

port

50 by manipulating

foot pedal

120 to generate an input signal 124 for

proportional valve

102. More specifically, the surgeon can gradually open

proportional valve

102 by depressing

foot pedal

120 and can gradually close

proportional valve

102 by “letting up” on

foot pedal

120. The degree to which

proportional valve

102 is open determines the pressure and air flow rate delivered to

manifold

105 or

manifold

114. The greater the air flow through

proportional valve

102, the greater the vacuum supplied to

port

52, or the greater the pressure supplied to

port

50. Although not shown in the block diagram of FIG. 2, a process control system is preferably operatively coupled to

proportional valve

102,

vacuum pump

106,

vacuum manifold

110, second

valve output manifold

114, and

foot pedal

102 so as to give the surgeon precise control of the microsurgical instruments coupled to

ports

50 or 52 of

surgical system

10. The preferred process control system is described in detail in U.S. Pat. No. 5,674,194, which is commonly owned with the present invention and is incorporated herein in its entirety by reference.

FIG. 3 illustrates preferred embodiments of

solenoid valve

150 and

reservoir

151.

Tubing

152 supplies pneumatic pressure from second

valve output manifold

114 to

solenoid valve

150, manifold 115,

reservoir

151, manifold 116, and port or

pneumatic connector

50.

Tubing

152 is preferably conventional PVC tubing.

Tubing

152,

solenoid valve

150, manifold 115,

reservoir

151, and

manifold

116 are preferably located within

housing

11 of

surgical system

10 generally behind

port

50.

Although not shown in FIG. 3,

reservoir

151 may also be located external to

housing

11 of

surgical system

10. For example,

reservoir

151 may be fluidly coupled to

tubing

58, as shown schematically in FIG. 1. As another example,

syringe

56 may be modified from its conventional form to include

reservoir

151 proximate its

end

54. As a further example, the length and/or inner diameter of

tubing

58 may be modified from its conventional form so as to incorporate the volume of

reservoir

151.

FIG. 4 schematically illustrates a preferred embodiment of

foot pedal

120 according to the present invention.

Foot pedal

120 has a

first position

200 corresponding to a fully undepressed position, a

second position

202 corresponding to a fully depressed position, and a

third position

204 corresponding to an about one-third depressed position.

Position

204 is preferably indicated by a mechanical detent of

foot pedal

120.

Foot pedal

120 may be made by modifying the conventional foot pedal sold as part of the Accurus® surgical system mentioned hereinabove.

A conventional

surgical system

10 is limited by the fact that it cannot supply pneumatic pressure to port 50 for the injection of

viscous fluid

12 into

eye

14 simultaneously with supplying vacuum to

port

52 for the aspiration of viscous fluid 16 from

eye

14. However, the addition of

solenoid valve

150,

reservoir

151, and

manifolds

115 and 116 enable the delivery of a substantially constant pneumatic pressure to port 50 while proportional vacuum is also provided to

port

52. Significantly, this ability allows the surgeon to minimize the potential of slippage of

retina

28 and to maintain the intraocular pressure of

eye

14 at a level very close to the desired intraocular pressure during the fluid/fluid exchange.

Referring again to FIGS. 1 and 2, a first volume V₁may be defined by the volume of air within

manifold

115,

reservoir

151, manifold 116,

tubing

58, and

syringe

56 on the side of

plunger

proximate tubing

58. A second volume V₂may be defined by the volume of

posterior segment

13 of

eye

14 to be filled with

silicone oil

12. As

silicone oil

12 is injected into

eye

14,

syringe plunger

68 moves toward

end

60 of

syringe

56, increasing the volume of V₁by the amount of oil injected. When all of the

posterior segment

13 of

eye

14 is filled with

silicone oil

12, volume V₁will have increased by an amount V₂. By using

reservoir

151 to make volume V₁substantially larger than volume V₂, the silicone oil injection pressure can be maintained at a substantially constant pressure. More specifically, defining the initial silicone oil injection pressure in V₁as P₁and the post-injection pressure as P₂with a volume of V₁+V₂, Boyle's Law shows that P₁will be approximately equal to P₂if V₂is small with respect to V₁: P₂=P₁×(V₁/(V₁+V₂))=>P₂≅P₁, if V₁≅V₁+V₂when V₂<<V₁.

At some point during the injection of

silicone oil

12, the surgeon will also begin aspirating perfluorocarbon liquid 16 to counteract the rise in intraocular pressure caused by the injection of

silicone oil

12. As is explained in more detail hereinbelow, when a surgeon initiates aspiration of perfluorocarbon liquid 16 from

posterior segment

13,

solenoid valve

150 closes, eliminating the pneumatic pressure supplied from

proportional valve

102, but isolating the silicone oil injection pressure in

manifold

115,

reservoir

151, manifold 116,

tubing

58, and

syringe

56. The isolated silicone oil injection pressure insures continued flow of

silicone oil

12 into

eye

14 via

tubing

64.

FIG. 5 further illustrates how

reservoir

151 functions to keep silicone oil injection pressure P₁substantially constant during the injection of

silicone oil

12. For one preferred embodiment of

surgical system

10,

tubing

58 and

syringe

56 on the side of

plunger

proximate tubing

58 have a volume V₀of about twenty two (22) cubic centimeters, and

reservoir

151 has a volume of about 12.5 cubic centimeters. For a typical adult human eye, the volume V₂of

posterior segment

13 to be filled with

silicone oil

12 is about 5 cubic centimeters. When V₀was increased by V₂, as would occur during the injection of 5 cubic centimeters of silicone oil, an injection pressure P₀of about 40 psi decreased about 7 psig (about 17.5 percent). In contrast, with a

reservoir

151 having a volume of 12.5 cubic centimeters added to V₀for a total volume V₁of about 34.5 cubic centimeters, an injection pressure P₁of about 40 psi decreased only about 4.8 psig (about 12 percent) when V₁was increased by V₂. As another example, an injection pressure P₀of about 80 psi decreased about 14 psig (about 17.5 percent) when V₀was increased by V₂. In contrast, with a

rescrvoir

151 having a volume of 12.5 cubic centimeters added to V₀for a total volume V₁of about 34.5 cubic centimeters, an injection pressure P₁of about 80 psi decreased only about 9.8 psig (about 12 percent) when V₁was increased by V₂. Similar variances of P₁were observed for injection pressures of 50 psi, 60 psi, and 70 psi, as shown in FIG. 5. Boyle's Law shows that the variance of P₁may be reduced below 12 percent by increasing the volume of

reservoir

151, if desired, for specific

surgical systems

10. For example, this variance of P₁may be reduced to 10 percent, 8 percent, 6 percent, 4 percent, 2 percent, or below.

Referring to FIGS. 1 through 5, the preferred method of operating

foot pedal

120 according to the present invention so as to perform a fluid/fluid exchange of

perfluorocarbon liquid

16 and

siliconc oil

12 is described in greater detail. When

foot pedal

120 is in

position

200,

proportional valve

102 does not supply pneumatic pressure or vacuum to

ports

50 or 52, respectively.

Solenoid valve

103 is in the closed position, and

solenoid valve

150 is in the open position.

Silicone oil

12 is not being injected into

posterior segment

13 via

infusion cannula

62, and

perfluorocarbon liquid

16 is not being aspirated via aspiration probe 76.

When a surgeon gradually moves

foot pedal

120 from

position

200 to

position

204, pneumatic pressure is supplied to

manifold

115,

reservoir

151, manifold 116,

port

50,

tubing

58, and

syringe

56 in gradually increasing amounts. This is accomplished via a change in electrical signal 124 from

foot pedal

120 to

proportional valve

102 communicated via electrical cabling 122. The minimum pneumatic pressure is preferably 0 psi (position 200), and the maximum pneumatic pressure is preferably about 80 psi (position 204). Such proportional pneumatic pressure causes

silicone oil

12 from

syringe

56 and

tubing

64 to be injected into

posterior segment

13 via

infusion cannula

62. During this process, a clamping mechanism (not shown) within

surgical cassette

72 is preferably in the closed position to prevent passive flow of perfluorocarbon liquid 16 into

surgical cassette

72. Therefore, the intraocular pressure of

eye

14 gradually begins to rise.

If the surgeon applies additional downward force to foot pedal 120 at

position

204, he or she overcomes a mechanical detent in

foot pedal

120. While overcoming this detent, the printed circuit board electronics of

surgical system

close solenoid valve

150 and

open solenoid valve

103, fluidly coupling

vacuum pump

106 to first

valve output manifold

105. Closure of

solenoid valve

150 causes the injection pressure P₁in

manifold

115,

reservoir

151, manifold 116,

port

50,

tubing

58, and

syringe

56 to be maintained, resulting in the continued flow of silicone oil into

eye

14 via

tubing

64. Furthermore, the printed circuit board electronics of

surgical system

10 actuate the clamping mechanism within

surgical cassette

72 to an open position allowing flow of perfluorocarbon liquid 16 from

tubing

78 into

cassette

72.

When a surgeon gradually moves

foot pedal

120 from

position

204 to

position

202, vacuum is supplied to

port

52,

tubing

78, aspiration probe 76, and

extrusion cannula

77 in increasing amounts. This is accomplished via a change in electrical signal 124 from

foot pedal

120 to

proportional valve

102 communicated via electrical cabling 122. The minimum vacuum is preferably 0 mmHg (position 204), and the maximum vacuum is preferably about 600 mmHg (position 202). Such proportional vacuum causes perfluorocarbon

liquid

16 to be aspirated from

posterior segment

13 into

cassette

72 and

collection bag

74. This vacuum counteracts the rise in intraocular pressure caused by the injection of

silicone oil

12.

As the intraocular pressure begins to decrease due to aspiration of

perfluorocarbon liquid

16, the surgeon lets up on

foot pedal

120, controlling the flow of aspirated

perfluorocarbon liquid

16 to more closely match the injection flow rate of

silicone oil

12. In this manner, the surgeon quickly brings the intraocular pressure to its desired level.

During this replacement of perfluorocarbon liquid 16 with

silicone oil

12, the surgeon visually monitors

eye

14 to prevent the intraocular pressure from rising to a dangerously high level (a “hard eye” condition) or to a dangerously low level (a “soft eye” condition). Significantly, because of the added volume of

reservoir

151 and

solenoid valve

150, the silicone oil injection pressure P₁remains substantially constant during the aspiration of

perfluorocarbon liquid

16. This, combined with the design of

foot pedal

120, allows the surgeon to more effectively control the intraocular pressure of

eye

14, minimizing risk to the patient.

From the above, it may be appreciated that the present invention provides improved apparatus and methods for tamponading a retinal tear or detachment. The present invention minimizes retinal slippage and variations in intraocular pressure during a fluid/fluid exchange. The present invention also provides the surgeon with an easier method of controlling a fluid/fluid exchange.

The present invention is illustrated herein by example, and various modifications may be made by a person of ordinary skill in the art. For example, although the preferred apparatus and methods are described hereinabove in connection with a fluid/fluid exchange of perfluorocarbon liquid and silicone oil in vitreoretinal surgery, the present invention is applicable to the simultaneous injection and aspiration of other viscous fluids. As another example, the present invention is also applicable to other types of surgeries other than vitreoretinal surgery.

It is believed that the operation and construction of the present invention will be apparent from the foregoing description. While the apparatus and methods shown or described above have been characterized as being preferred, various changes and modifications may be made therein without departing from the spirit and scope of the invention as defined in the following claims.

Claims (21)

What is claimed is:

1. A method of injecting a first viscous fluid into a posterior segment of an eye simultaneous with aspirating a second viscous fluid from said posterior segment, comprising the steps of:

providing a surgical system capable of supplying pneumatic pressure and vacuum;

injecting said first viscous fluid into said posterior segment using pneumatic pressure from said system;

changing a mode of operation of said system to provide vacuum and pneumatic pressure; and

aspirating said second viscous fluid from said posterior segment using vacuum from said system;

wherein said pneumatic pressure exhibits a decrease of about twelve percent or less during said aspirating step.

2. The method of claim 1 wherein said eye is a a human eye.

3. The method of claim 1 wherein said first viscous fluid comprises a silicone oil, said second viscous fluid comprises a perfluorocarbon liquid.

4. A surgical system for injecting a first retinal tamponading fluid into a posterior segment of an eye simultaneous with aspirating a second retinal tamponading fluid from said posterior segment, said posterior segment having a volume, comprising:

a single pneumatic assembly capable of supplying pneumatic pressure and vacuum, said assembly comprising:

a regulated pressure source;

a proportional valve fluidly coupled to said regulated pressure source;

a vacuum pump fluidly coupled to said proportional valve; and

a reservoir fluidly coupled to said proportional valve;

a syringe having:

a hollow bore with a first end and a second end; and

a plunger movably disposed in said hollow bore between said first end and said second end; and

tubing fluidly coupling said first end of said hollow bore on a side assembly;

wherein a volume of said reservoir, said tubing, and said hollow bore on a side of said plunger proximate said first end is greater than said volume of said posterior segment.

5. The surgical system of claim 4 further compressing:

an infusion cannula fluidly coupled to said syringe;

an aspiration probe fluidly coupled to said assembly; and

an extrusion cannula coupled to said aspiration probe.

6. The surgical system of claim 5 wherein said infusion cannula end said extrusion cannula are for insertion into said posterior segment.

7. The surgical system of claim 4 further comprising a housing and wherein:

said assembly is disposed within said housing;

said reservoir is fluidly coupled with said tubing and said syringe; and

said tubing and said syringe are disposed outside of said housing.

8. A surgical system for injecting a first viscous fluid into a target tissue simultaneous with aspirating a second viscous fluid from said target tissue, comprising:

an assembly capable of supplying pneumatic pressure and vacuum to at least one microsurgical instrument;

a foot pedal, operatively coupled to said assembly, comprising:

a first range of motion in a generally vertical plane in which said assembly supplies proportional pneumatic pressure; and

a second range of motion in a generally vertical plane in which said assembly supplies a substantially constant pneumatic pressure and proportional vacuum.

9. The surgical system of claim 8 wherein said foot pedal comprises a mechanical detent separating said first range of motion and said second range of motion.

10. The surgical system of claim 9 wherein said first range of motion is from a first position corresponding to a fully undepressed position, to a second position corresponding to said mechanical detent.

11. The surgical system of claim 10 wherein said second range of motion is from said second position to a third position corresponding to a fully depressed position.

12. The surgical system of claim 11 wherein moving said foot pedal in said first range of motion toward said second position increases an amount of pneumatic pressure supplied by said assembly.

13. The surgical system of claim 11 wherein moving said foot pedal in said second range of motion toward said third position increases an amount of vacuum supplied by said assembly.

14. The surgical system of claim 8 wherein said first range of motion comprises about one third of a full range of motion in a generally vertical plane of said foot pedal.

15. The surgical system of claim 8 further comprising:

an infusion cannula and a syringe for injecting said first viscous fluid into said target tissue; and

an aspiration probe and an extrusion cannula for aspirating said second viscous fluid from said target tissue.

16. The surgical system of claim 8 wherein said substantially constant pneumatic pressure comprises a pneumatic pressure decrease of about twelve precent or less.

17. A surgical system for injecting a silicone oil into a posterior segment of an eye simultaneous with aspirating a perfluorocarbon liquid from said posterior segment, said posterior segment having a volume, comprising:

a single pneumatic assembly capable of supplying pneumatic pressure and vacuum, said assembly comprising:

a regulated pressure source

a proportional valve fluidly coupled to said regulated pressure source;

a vacuum pump fluidly coupled to said proportional valve; and

a reservoir fluidly coupled to said proportional valve;

a syringe having:

a hollow bore with a first end and a second end; and

a plunger movably disposed in said hollow bore between said first end and said second end; and

tubing fluidly coupling said first end of said hollow bore to said assembly;

wherein a volume of said reservoir, said tubing, and said hollow bore on a side of said plunger proximate said first end is greater than said volume of said posterior segment.

18. A surgical system for injecting a first retinal tamponading fluid into a posterior segment of an eye simultaneous with aspirating a second retinal tamponading fluid from said posterior segment, comprising:

an assembly capable of supplying pneumatic pressure and vacuum to at least one microsurgical instrument;

a foot pedal, operatively coupled to said assembly, comprising:

a first range of motion in a generally vertical plane in which said assembly supplies proportional pneumatic pressure; and

a second range of motion in a generally vertical plane in which said assembly supplies a substantially constant pneumatic pressure and proportional vacuum.

19. The surgical system of claim 18 wherein said substantially constant pneumatic pressure comprises a pneumatic pressure decrease of about twelve percent or less.

20. A surgical system for injecting a silicone oil into a posterior segment of an eye simultaneous with aspirating a perfluorocarbon liquid from said posterior segment, comprising:

an assembly capable of supplying pneumatic pressure and vacuum to at least one microsurgical instrument;

a foot pedal, operatively coupled to said assembly, comprising:

a first range of motion in a generally vertical plane in which said assembly supplies proportional pneumatic pressure; and

a second range of motion in a generally vertical plane in which said assembly supplies a substantially constant pneumatic pressure and proportional vacuum.

21. The surgical system of claim 20 wherein said substantially constant pneumatic pressure comprises a pneumatic pressure decrease of about twelve percent or less.

US09/336,922 1999-06-21 1999-06-21 Simultaneous injection and aspiration of viscous fluids in a surgical system Expired - Lifetime US6290690B1 (en)

Priority Applications (14)

Application Number	Priority Date	Filing Date	Title
US09/336,922 US6290690B1 (en)	1999-06-21	1999-06-21	Simultaneous injection and aspiration of viscous fluids in a surgical system
DE60004818T DE60004818T2 (en)	1999-06-21	2000-06-08	SIMULTANEOUSLY INJECTING AND SUCTIONING VISCOSES, SURGICAL LIQUIDS
PCT/US2000/015803 WO2000078257A1 (en)	1999-06-21	2000-06-08	Simultaneous injection and aspiration of viscous surgical fluids
ES00942710T ES2203491T3 (en)	1999-06-21	2000-06-08	SIMULTANEOUS INJECTION AND ASPIRATION OF VISCOSE SURGICAL FLUIDS.
JP2001504326A JP3845013B2 (en)	1999-06-21	2000-06-08	Surgical system
DK00942710T DK1180993T3 (en)	1999-06-21	2000-06-08	Simultaneous injection and extraction of viscous surgical fluids
AU57295/00A AU758704B2 (en)	1999-06-21	2000-06-08	Simultaneous injection and aspiration of viscous surgical fluids
CA002371877A CA2371877C (en)	1999-06-21	2000-06-08	Simultaneous injection and aspiration of viscous surgical fluids
CA002547297A CA2547297C (en)	1999-06-21	2000-06-08	Simultaneous injection and aspiration of viscous surgical fluids
PT00942710T PT1180993E (en)	1999-06-21	2000-06-08	INJECTION AND SIMULTANEOUS ASPIRATION OF VISCOUS SURGICAL FLUIDS
EP03001000A EP1302185B8 (en)	1999-06-21	2000-06-08	Simultaneous surgical injection and aspiration with pedal control
AT00942710T ATE247939T1 (en)	1999-06-21	2000-06-08	SIMULTANEOUS INJECT AND SUCTION OF VISCOUS SURGICAL FLUIDS
EP00942710A EP1180993B1 (en)	1999-06-21	2000-06-08	Simultaneous injection and aspiration of viscous surgical fluids
JP2006145723A JP4602935B2 (en)	1999-06-21	2006-05-25	Simultaneous injection and suction of surgical viscous fluid

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
US09/336,922 US6290690B1 (en)	1999-06-21	1999-06-21	Simultaneous injection and aspiration of viscous fluids in a surgical system

Publications (1)

Publication Number	Publication Date
US6290690B1 true US6290690B1 (en)	2001-09-18

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Family Applications (1)

Application Number	Title	Priority Date	Filing Date
US09/336,922 Expired - Lifetime US6290690B1 (en)	1999-06-21	1999-06-21	Simultaneous injection and aspiration of viscous fluids in a surgical system